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similaritytransform.py
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similaritytransform.py
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# From scikit-image
import math
import numpy as np
import sys
import textwrap
def get_bound_method_class(m):
"""Return the class for a bound method.
"""
return m.im_class if sys.version < '3' else m.__self__.__class__
def safe_as_int(val, atol=1e-3):
"""
Attempt to safely cast values to integer format.
Parameters
----------
val : scalar or iterable of scalars
Number or container of numbers which are intended to be interpreted as
integers, e.g., for indexing purposes, but which may not carry integer
type.
atol : float
Absolute tolerance away from nearest integer to consider values in
``val`` functionally integers.
Returns
-------
val_int : NumPy scalar or ndarray of dtype `np.int64`
Returns the input value(s) coerced to dtype `np.int64` assuming all
were within ``atol`` of the nearest integer.
Notes
-----
This operation calculates ``val`` modulo 1, which returns the mantissa of
all values. Then all mantissas greater than 0.5 are subtracted from one.
Finally, the absolute tolerance from zero is calculated. If it is less
than ``atol`` for all value(s) in ``val``, they are rounded and returned
in an integer array. Or, if ``val`` was a scalar, a NumPy scalar type is
returned.
If any value(s) are outside the specified tolerance, an informative error
is raised.
Examples
--------
>>> safe_as_int(7.0)
7
>>> safe_as_int([9, 4, 2.9999999999])
array([9, 4, 3])
>>> safe_as_int(53.1)
Traceback (most recent call last):
...
ValueError: Integer argument required but received 53.1, check inputs.
>>> safe_as_int(53.01, atol=0.01)
53
"""
mod = np.asarray(val) % 1 # Extract mantissa
# Check for and subtract any mod values > 0.5 from 1
if mod.ndim == 0: # Scalar input, cannot be indexed
if mod > 0.5:
mod = 1 - mod
else: # Iterable input, now ndarray
mod[mod > 0.5] = 1 - mod[mod > 0.5] # Test on each side of nearest int
try:
np.testing.assert_allclose(mod, 0, atol=atol)
except AssertionError:
raise ValueError("Integer argument required but received "
"{0}, check inputs.".format(val))
return np.round(val).astype(np.int64)
def _to_ndimage_mode(mode):
"""Convert from `numpy.pad` mode name to the corresponding ndimage mode."""
mode_translation_dict = dict(edge='nearest', symmetric='reflect',
reflect='mirror')
if mode in mode_translation_dict:
mode = mode_translation_dict[mode]
return mode
def _center_and_normalize_points(points):
"""Center and normalize image points.
The points are transformed in a two-step procedure that is expressed
as a transformation matrix. The matrix of the resulting points is usually
better conditioned than the matrix of the original points.
Center the image points, such that the new coordinate system has its
origin at the centroid of the image points.
Normalize the image points, such that the mean distance from the points
to the origin of the coordinate system is sqrt(2).
Parameters
----------
points : (N, 2) array
The coordinates of the image points.
Returns
-------
matrix : (3, 3) array
The transformation matrix to obtain the new points.
new_points : (N, 2) array
The transformed image points.
References
----------
.. [1] Hartley, Richard I. "In defense of the eight-point algorithm."
Pattern Analysis and Machine Intelligence, IEEE Transactions on 19.6
(1997): 580-593.
"""
centroid = np.mean(points, axis=0)
rms = math.sqrt(np.sum((points - centroid) ** 2) / points.shape[0])
norm_factor = math.sqrt(2) / rms
matrix = np.array([[norm_factor, 0, -norm_factor * centroid[0]],
[0, norm_factor, -norm_factor * centroid[1]],
[0, 0, 1]])
pointsh = np.row_stack([points.T, np.ones((points.shape[0]),)])
new_pointsh = (matrix @ pointsh).T
new_points = new_pointsh[:, :2]
new_points[:, 0] /= new_pointsh[:, 2]
new_points[:, 1] /= new_pointsh[:, 2]
return matrix, new_points
def _umeyama(src, dst, estimate_scale):
"""Estimate N-D similarity transformation with or without scaling.
Parameters
----------
src : (M, N) array
Source coordinates.
dst : (M, N) array
Destination coordinates.
estimate_scale : bool
Whether to estimate scaling factor.
Returns
-------
T : (N + 1, N + 1)
The homogeneous similarity transformation matrix. The matrix contains
NaN values only if the problem is not well-conditioned.
References
----------
.. [1] "Least-squares estimation of transformation parameters between two
point patterns", Shinji Umeyama, PAMI 1991, :DOI:`10.1109/34.88573`
"""
num = src.shape[0]
dim = src.shape[1]
# Compute mean of src and dst.
src_mean = src.mean(axis=0)
dst_mean = dst.mean(axis=0)
# Subtract mean from src and dst.
src_demean = src - src_mean
dst_demean = dst - dst_mean
# Eq. (38).
A = dst_demean.T @ src_demean / num
# Eq. (39).
d = np.ones((dim,), dtype=np.double)
if np.linalg.det(A) < 0:
d[dim - 1] = -1
T = np.eye(dim + 1, dtype=np.double)
U, S, V = np.linalg.svd(A)
# Eq. (40) and (43).
rank = np.linalg.matrix_rank(A)
if rank == 0:
return np.nan * T
elif rank == dim - 1:
if np.linalg.det(U) * np.linalg.det(V) > 0:
T[:dim, :dim] = U @ V
else:
s = d[dim - 1]
d[dim - 1] = -1
T[:dim, :dim] = U @ np.diag(d) @ V
d[dim - 1] = s
else:
T[:dim, :dim] = U @ np.diag(d) @ V
if estimate_scale:
# Eq. (41) and (42).
scale = 1.0 / src_demean.var(axis=0).sum() * (S @ d)
else:
scale = 1.0
T[:dim, dim] = dst_mean - scale * (T[:dim, :dim] @ src_mean.T)
T[:dim, :dim] *= scale
return T
class GeometricTransform(object):
"""Base class for geometric transformations.
"""
def __call__(self, coords):
"""Apply forward transformation.
Parameters
----------
coords : (N, 2) array
Source coordinates.
Returns
-------
coords : (N, 2) array
Destination coordinates.
"""
raise NotImplementedError()
def inverse(self, coords):
"""Apply inverse transformation.
Parameters
----------
coords : (N, 2) array
Destination coordinates.
Returns
-------
coords : (N, 2) array
Source coordinates.
"""
raise NotImplementedError()
def residuals(self, src, dst):
"""Determine residuals of transformed destination coordinates.
For each transformed source coordinate the euclidean distance to the
respective destination coordinate is determined.
Parameters
----------
src : (N, 2) array
Source coordinates.
dst : (N, 2) array
Destination coordinates.
Returns
-------
residuals : (N, ) array
Residual for coordinate.
"""
return np.sqrt(np.sum((self(src) - dst)**2, axis=1))
def __add__(self, other):
"""Combine this transformation with another.
"""
raise NotImplementedError()
class FundamentalMatrixTransform(GeometricTransform):
"""Fundamental matrix transformation.
The fundamental matrix relates corresponding points between a pair of
uncalibrated images. The matrix transforms homogeneous image points in one
image to epipolar lines in the other image.
The fundamental matrix is only defined for a pair of moving images. In the
case of pure rotation or planar scenes, the homography describes the
geometric relation between two images (`ProjectiveTransform`). If the
intrinsic calibration of the images is known, the essential matrix describes
the metric relation between the two images (`EssentialMatrixTransform`).
References
----------
.. [1] Hartley, Richard, and Andrew Zisserman. Multiple view geometry in
computer vision. Cambridge university press, 2003.
Parameters
----------
matrix : (3, 3) array, optional
Fundamental matrix.
Attributes
----------
params : (3, 3) array
Fundamental matrix.
"""
def __init__(self, matrix=None):
if matrix is None:
# default to an identity transform
matrix = np.eye(3)
if matrix.shape != (3, 3):
raise ValueError("Invalid shape of transformation matrix")
self.params = matrix
def __call__(self, coords):
"""Apply forward transformation.
Parameters
----------
coords : (N, 2) array
Source coordinates.
Returns
-------
coords : (N, 3) array
Epipolar lines in the destination image.
"""
coords_homogeneous = np.column_stack([coords, np.ones(coords.shape[0])])
return coords_homogeneous @ self.params.T
def inverse(self, coords):
"""Apply inverse transformation.
Parameters
----------
coords : (N, 2) array
Destination coordinates.
Returns
-------
coords : (N, 3) array
Epipolar lines in the source image.
"""
coords_homogeneous = np.column_stack([coords, np.ones(coords.shape[0])])
return coords_homogeneous @ self.params
def _setup_constraint_matrix(self, src, dst):
"""Setup and solve the homogeneous epipolar constraint matrix::
dst' * F * src = 0.
Parameters
----------
src : (N, 2) array
Source coordinates.
dst : (N, 2) array
Destination coordinates.
Returns
-------
F_normalized : (3, 3) array
The normalized solution to the homogeneous system. If the system
is not well-conditioned, this matrix contains NaNs.
src_matrix : (3, 3) array
The transformation matrix to obtain the normalized source
coordinates.
dst_matrix : (3, 3) array
The transformation matrix to obtain the normalized destination
coordinates.
"""
if src.shape != dst.shape:
raise ValueError('src and dst shapes must be identical.')
if src.shape[0] < 8:
raise ValueError('src.shape[0] must be equal or larger than 8.')
# Center and normalize image points for better numerical stability.
try:
src_matrix, src = _center_and_normalize_points(src)
dst_matrix, dst = _center_and_normalize_points(dst)
except ZeroDivisionError:
self.params = np.full((3, 3), np.nan)
return 3 * [np.full((3, 3), np.nan)]
# Setup homogeneous linear equation as dst' * F * src = 0.
A = np.ones((src.shape[0], 9))
A[:, :2] = src
A[:, :3] *= dst[:, 0, np.newaxis]
A[:, 3:5] = src
A[:, 3:6] *= dst[:, 1, np.newaxis]
A[:, 6:8] = src
# Solve for the nullspace of the constraint matrix.
_, _, V = np.linalg.svd(A)
F_normalized = V[-1, :].reshape(3, 3)
return F_normalized, src_matrix, dst_matrix
def estimate(self, src, dst):
"""Estimate fundamental matrix using 8-point algorithm.
The 8-point algorithm requires at least 8 corresponding point pairs for
a well-conditioned solution, otherwise the over-determined solution is
estimated.
Parameters
----------
src : (N, 2) array
Source coordinates.
dst : (N, 2) array
Destination coordinates.
Returns
-------
success : bool
True, if model estimation succeeds.
"""
F_normalized, src_matrix, dst_matrix = \
self._setup_constraint_matrix(src, dst)
# Enforcing the internal constraint that two singular values must be
# non-zero and one must be zero.
U, S, V = np.linalg.svd(F_normalized)
S[2] = 0
F = U @ np.diag(S) @ V
self.params = dst_matrix.T @ F @ src_matrix
return True
def residuals(self, src, dst):
"""Compute the Sampson distance.
The Sampson distance is the first approximation to the geometric error.
Parameters
----------
src : (N, 2) array
Source coordinates.
dst : (N, 2) array
Destination coordinates.
Returns
-------
residuals : (N, ) array
Sampson distance.
"""
src_homogeneous = np.column_stack([src, np.ones(src.shape[0])])
dst_homogeneous = np.column_stack([dst, np.ones(dst.shape[0])])
F_src = self.params @ src_homogeneous.T
Ft_dst = self.params.T @ dst_homogeneous.T
dst_F_src = np.sum(dst_homogeneous * F_src.T, axis=1)
return np.abs(dst_F_src) / np.sqrt(F_src[0] ** 2 + F_src[1] ** 2
+ Ft_dst[0] ** 2 + Ft_dst[1] ** 2)
class EssentialMatrixTransform(FundamentalMatrixTransform):
"""Essential matrix transformation.
The essential matrix relates corresponding points between a pair of
calibrated images. The matrix transforms normalized, homogeneous image
points in one image to epipolar lines in the other image.
The essential matrix is only defined for a pair of moving images capturing a
non-planar scene. In the case of pure rotation or planar scenes, the
homography describes the geometric relation between two images
(`ProjectiveTransform`). If the intrinsic calibration of the images is
unknown, the fundamental matrix describes the projective relation between
the two images (`FundamentalMatrixTransform`).
References
----------
.. [1] Hartley, Richard, and Andrew Zisserman. Multiple view geometry in
computer vision. Cambridge university press, 2003.
Parameters
----------
rotation : (3, 3) array, optional
Rotation matrix of the relative camera motion.
translation : (3, 1) array, optional
Translation vector of the relative camera motion. The vector must
have unit length.
matrix : (3, 3) array, optional
Essential matrix.
Attributes
----------
params : (3, 3) array
Essential matrix.
"""
def __init__(self, rotation=None, translation=None, matrix=None):
if rotation is not None:
if translation is None:
raise ValueError("Both rotation and translation required")
if rotation.shape != (3, 3):
raise ValueError("Invalid shape of rotation matrix")
if abs(np.linalg.det(rotation) - 1) > 1e-6:
raise ValueError("Rotation matrix must have unit determinant")
if translation.size != 3:
raise ValueError("Invalid shape of translation vector")
if abs(np.linalg.norm(translation) - 1) > 1e-6:
raise ValueError("Translation vector must have unit length")
# Matrix representation of the cross product for t.
t_x = np.array([0, -translation[2], translation[1],
translation[2], 0, -translation[0],
-translation[1], translation[0], 0]).reshape(3, 3)
self.params = t_x @ rotation
elif matrix is not None:
if matrix.shape != (3, 3):
raise ValueError("Invalid shape of transformation matrix")
self.params = matrix
else:
# default to an identity transform
self.params = np.eye(3)
def estimate(self, src, dst):
"""Estimate essential matrix using 8-point algorithm.
The 8-point algorithm requires at least 8 corresponding point pairs for
a well-conditioned solution, otherwise the over-determined solution is
estimated.
Parameters
----------
src : (N, 2) array
Source coordinates.
dst : (N, 2) array
Destination coordinates.
Returns
-------
success : bool
True, if model estimation succeeds.
"""
E_normalized, src_matrix, dst_matrix = \
self._setup_constraint_matrix(src, dst)
# Enforcing the internal constraint that two singular values must be
# equal and one must be zero.
U, S, V = np.linalg.svd(E_normalized)
S[0] = (S[0] + S[1]) / 2.0
S[1] = S[0]
S[2] = 0
E = U @ np.diag(S) @ V
self.params = dst_matrix.T @ E @ src_matrix
return True
class ProjectiveTransform(GeometricTransform):
r"""Projective transformation.
Apply a projective transformation (homography) on coordinates.
For each homogeneous coordinate :math:`\mathbf{x} = [x, y, 1]^T`, its
target position is calculated by multiplying with the given matrix,
:math:`H`, to give :math:`H \mathbf{x}`::
[[a0 a1 a2]
[b0 b1 b2]
[c0 c1 1 ]].
E.g., to rotate by theta degrees clockwise, the matrix should be::
[[cos(theta) -sin(theta) 0]
[sin(theta) cos(theta) 0]
[0 0 1]]
or, to translate x by 10 and y by 20::
[[1 0 10]
[0 1 20]
[0 0 1 ]].
Parameters
----------
matrix : (3, 3) array, optional
Homogeneous transformation matrix.
Attributes
----------
params : (3, 3) array
Homogeneous transformation matrix.
"""
_coeffs = range(8)
def __init__(self, matrix=None):
if matrix is None:
# default to an identity transform
matrix = np.eye(3)
if matrix.shape != (3, 3):
raise ValueError("invalid shape of transformation matrix")
self.params = matrix
@property
def _inv_matrix(self):
return np.linalg.inv(self.params)
def _apply_mat(self, coords, matrix):
coords = np.array(coords, copy=False, ndmin=2)
x, y = np.transpose(coords)
src = np.vstack((x, y, np.ones_like(x)))
dst = src.T @ matrix.T
# below, we will divide by the last dimension of the homogeneous
# coordinate matrix. In order to avoid division by zero,
# we replace exact zeros in this column with a very small number.
dst[dst[:, 2] == 0, 2] = np.finfo(float).eps
# rescale to homogeneous coordinates
dst[:, :2] /= dst[:, 2:3]
return dst[:, :2]
def __call__(self, coords):
"""Apply forward transformation.
Parameters
----------
coords : (N, 2) array
Source coordinates.
Returns
-------
coords : (N, 2) array
Destination coordinates.
"""
return self._apply_mat(coords, self.params)
def inverse(self, coords):
"""Apply inverse transformation.
Parameters
----------
coords : (N, 2) array
Destination coordinates.
Returns
-------
coords : (N, 2) array
Source coordinates.
"""
return self._apply_mat(coords, self._inv_matrix)
def estimate(self, src, dst):
"""Estimate the transformation from a set of corresponding points.
You can determine the over-, well- and under-determined parameters
with the total least-squares method.
Number of source and destination coordinates must match.
The transformation is defined as::
X = (a0*x + a1*y + a2) / (c0*x + c1*y + 1)
Y = (b0*x + b1*y + b2) / (c0*x + c1*y + 1)
These equations can be transformed to the following form::
0 = a0*x + a1*y + a2 - c0*x*X - c1*y*X - X
0 = b0*x + b1*y + b2 - c0*x*Y - c1*y*Y - Y
which exist for each set of corresponding points, so we have a set of
N * 2 equations. The coefficients appear linearly so we can write
A x = 0, where::
A = [[x y 1 0 0 0 -x*X -y*X -X]
[0 0 0 x y 1 -x*Y -y*Y -Y]
...
...
]
x.T = [a0 a1 a2 b0 b1 b2 c0 c1 c3]
In case of total least-squares the solution of this homogeneous system
of equations is the right singular vector of A which corresponds to the
smallest singular value normed by the coefficient c3.
In case of the affine transformation the coefficients c0 and c1 are 0.
Thus the system of equations is::
A = [[x y 1 0 0 0 -X]
[0 0 0 x y 1 -Y]
...
...
]
x.T = [a0 a1 a2 b0 b1 b2 c3]
Parameters
----------
src : (N, 2) array
Source coordinates.
dst : (N, 2) array
Destination coordinates.
Returns
-------
success : bool
True, if model estimation succeeds.
"""
try:
src_matrix, src = _center_and_normalize_points(src)
dst_matrix, dst = _center_and_normalize_points(dst)
except ZeroDivisionError:
self.params = np.nan * np.empty((3, 3))
return False
xs = src[:, 0]
ys = src[:, 1]
xd = dst[:, 0]
yd = dst[:, 1]
rows = src.shape[0]
# params: a0, a1, a2, b0, b1, b2, c0, c1
A = np.zeros((rows * 2, 9))
A[:rows, 0] = xs
A[:rows, 1] = ys
A[:rows, 2] = 1
A[:rows, 6] = - xd * xs
A[:rows, 7] = - xd * ys
A[rows:, 3] = xs
A[rows:, 4] = ys
A[rows:, 5] = 1
A[rows:, 6] = - yd * xs
A[rows:, 7] = - yd * ys
A[:rows, 8] = xd
A[rows:, 8] = yd
# Select relevant columns, depending on params
A = A[:, list(self._coeffs) + [8]]
_, _, V = np.linalg.svd(A)
# if the last element of the vector corresponding to the smallest
# singular value is close to zero, this implies a degenerate case
# because it is a rank-defective transform, which would map points
# to a line rather than a plane.
if np.isclose(V[-1, -1], 0):
return False
H = np.zeros((3, 3))
# solution is right singular vector that corresponds to smallest
# singular value
H.flat[list(self._coeffs) + [8]] = - V[-1, :-1] / V[-1, -1]
H[2, 2] = 1
# De-center and de-normalize
H = np.linalg.inv(dst_matrix) @ H @ src_matrix
self.params = H
return True
def __add__(self, other):
"""Combine this transformation with another.
"""
if isinstance(other, ProjectiveTransform):
# combination of the same types result in a transformation of this
# type again, otherwise use general projective transformation
if type(self) == type(other):
tform = self.__class__
else:
tform = ProjectiveTransform
return tform(other.params @ self.params)
elif (hasattr(other, '__name__')
and other.__name__ == 'inverse'
and hasattr(get_bound_method_class(other), '_inv_matrix')):
return ProjectiveTransform(other.__self__._inv_matrix @ self.params)
else:
raise TypeError("Cannot combine transformations of differing "
"types.")
def __nice__(self):
"""common 'paramstr' used by __str__ and __repr__"""
npstring = np.array2string(self.params, separator=', ')
paramstr = 'matrix=\n' + textwrap.indent(npstring, ' ')
return paramstr
def __repr__(self):
"""Add standard repr formatting around a __nice__ string"""
paramstr = self.__nice__()
classname = self.__class__.__name__
classstr = classname
return '<{}({}) at {}>'.format(classstr, paramstr, hex(id(self)))
def __str__(self):
"""Add standard str formatting around a __nice__ string"""
paramstr = self.__nice__()
classname = self.__class__.__name__
classstr = classname
return '<{}({})>'.format(classstr, paramstr)
class AffineTransform(ProjectiveTransform):
"""2D affine transformation.
Has the following form::
X = a0*x + a1*y + a2 =
= sx*x*cos(rotation) - sy*y*sin(rotation + shear) + a2
Y = b0*x + b1*y + b2 =
= sx*x*sin(rotation) + sy*y*cos(rotation + shear) + b2
where ``sx`` and ``sy`` are scale factors in the x and y directions,
and the homogeneous transformation matrix is::
[[a0 a1 a2]
[b0 b1 b2]
[0 0 1]]
Parameters
----------
matrix : (3, 3) array, optional
Homogeneous transformation matrix.
scale : {s as float or (sx, sy) as array, list or tuple}, optional
Scale factor(s). If a single value, it will be assigned to both
sx and sy.
.. versionadded:: 0.17
Added support for supplying a single scalar value.
rotation : float, optional
Rotation angle in counter-clockwise direction as radians.
shear : float, optional
Shear angle in counter-clockwise direction as radians.
translation : (tx, ty) as array, list or tuple, optional
Translation parameters.
Attributes
----------
params : (3, 3) array
Homogeneous transformation matrix.
"""
_coeffs = range(6)
def __init__(self, matrix=None, scale=None, rotation=None, shear=None,
translation=None):
params = any(param is not None
for param in (scale, rotation, shear, translation))
if params and matrix is not None:
raise ValueError("You cannot specify the transformation matrix and"
" the implicit parameters at the same time.")
elif matrix is not None:
if matrix.shape != (3, 3):
raise ValueError("Invalid shape of transformation matrix.")
self.params = matrix
elif params:
if scale is None:
scale = (1, 1)
if rotation is None:
rotation = 0
if shear is None:
shear = 0
if translation is None:
translation = (0, 0)
if np.isscalar(scale):
sx = sy = scale
else:
sx, sy = scale
self.params = np.array([
[sx * math.cos(rotation), -sy * math.sin(rotation + shear), 0],
[sx * math.sin(rotation), sy * math.cos(rotation + shear), 0],
[ 0, 0, 1]
])
self.params[0:2, 2] = translation
else:
# default to an identity transform
self.params = np.eye(3)
@property
def scale(self):
sx = math.sqrt(self.params[0, 0] ** 2 + self.params[1, 0] ** 2)
sy = math.sqrt(self.params[0, 1] ** 2 + self.params[1, 1] ** 2)
return sx, sy
@property
def rotation(self):
return math.atan2(self.params[1, 0], self.params[0, 0])
@property
def shear(self):
beta = math.atan2(- self.params[0, 1], self.params[1, 1])
return beta - self.rotation
@property
def translation(self):
return self.params[0:2, 2]
class EuclideanTransform(ProjectiveTransform):
"""2D Euclidean transformation.
Has the following form::
X = a0 * x - b0 * y + a1 =
= x * cos(rotation) - y * sin(rotation) + a1
Y = b0 * x + a0 * y + b1 =
= x * sin(rotation) + y * cos(rotation) + b1
where the homogeneous transformation matrix is::
[[a0 b0 a1]
[b0 a0 b1]
[0 0 1]]
The Euclidean transformation is a rigid transformation with rotation and
translation parameters. The similarity transformation extends the Euclidean
transformation with a single scaling factor.
Parameters
----------
matrix : (3, 3) array, optional
Homogeneous transformation matrix.
rotation : float, optional
Rotation angle in counter-clockwise direction as radians.
translation : (tx, ty) as array, list or tuple, optional
x, y translation parameters.
Attributes
----------
params : (3, 3) array
Homogeneous transformation matrix.
"""
def __init__(self, matrix=None, rotation=None, translation=None):
params = any(param is not None
for param in (rotation, translation))
if params and matrix is not None:
raise ValueError("You cannot specify the transformation matrix and"
" the implicit parameters at the same time.")
elif matrix is not None:
if matrix.shape != (3, 3):
raise ValueError("Invalid shape of transformation matrix.")
self.params = matrix
elif params:
if rotation is None:
rotation = 0
if translation is None:
translation = (0, 0)
self.params = np.array([
[math.cos(rotation), - math.sin(rotation), 0],
[math.sin(rotation), math.cos(rotation), 0],
[ 0, 0, 1]
])
self.params[0:2, 2] = translation
else:
# default to an identity transform
self.params = np.eye(3)
def estimate(self, src, dst):
"""Estimate the transformation from a set of corresponding points.
You can determine the over-, well- and under-determined parameters
with the total least-squares method.
Number of source and destination coordinates must match.
Parameters
----------
src : (N, 2) array
Source coordinates.
dst : (N, 2) array
Destination coordinates.
Returns
-------